ISSN : 1301-5680
e-ISSN : 2149-8156
Turkish Journal of Thoracic and Cardiovascular Surgery     
The analysis of unplanned readmissions after left ventricular assist device implantation as bridge-to-transplant
Murat Sezgin1, Murat Bülent Rabuş2, Emre Selçuk3, Özge Altaş2, Sabit Sarıkaya2, Mehmet Balkanay4, Mehmet Kaan Kırali2
1Department of Cardiovascular Surgery, Tunceli State Hospital, Tunceli, Turkey
2Department of Cardiovascular Surgery, Istanbul Kartal Koşuyolu Yüksek Ihtisas Training and Research Hospital, Istanbul, Turkey
3Department of Cardiovascular Surgery, Muş State Hospital, Muş, Turkey
4Department of Cardiovascular Surgery, Yeni Yüzyıl University Medical Faculty, Istanbul, Turkey
DOI : 10.5606/tgkdc.dergisi.2020.18836

Abstract

Background: In this study, we aimed to investigate frequency, patterns, etiologies, and costs of unplanned readmissions after left ventricular assist device implantation.

Methods: Between April 2012 and September 2016, 99 unplanned readmissions of a total of 50 consecutive bridge-to-transplant patients (45 males, 5 females; mean age 46.9±10.3 years; range, 19 to 67 years) who were successfully discharged after left ventricular assist device implantation were retrospectively analyzed. Patient demographic data, hemodynamic measurements before implantation, and readmissions after discharge were recorded. Hospitalizations due to major problems which were unable to be managed in routine outpatient clinic were accepted as unplanned readmissions. Survival analysis was performed.

Results: The readmission rate was 1.7 per year after discharge. Survival of patients who were readmitted within the first 90 days was found to be significantly lower than those without early readmission. The most common reasons of readmissions during follow-up were major infection (23.2%), neurological dysfunction (22.2%), cardiac causes (12.1%), bleeding (11.1%), and device malfunction (10.1%). Neurological dysfunctions (82,005 USD) and device malfunctions (73,300 USD) caused the highest economic burden.

Conclusion: Among patients with a left ventricular assist device, hospital readmissions are common. Development of preventive strategies as well as effective treatment methods focused on longterm adverse events is critical to reduce the frequency and costs of hospital readmissions.

Left ventricular assist device (LVAD) therapy is a suitable option for patients in whom optimal advanced heart failure treatment fails.[1] Although LVADs provide excellent hemodynamic support, long-term use of them eventually induces various multifactorial complications.[2] In bridge-to-transplant (BTT) patients with LVAD, prolongation of support time due to donor scarcity may lead to many unplanned hospital readmissions which health professionals must have to handle.[3] Previous reports have revealed that readmission rate is around 80% during follow-up, and most of them are unplanned.[4,5] Due to the rapid increase and diversification of this specific patient population, it is important to analyze the problems encountered in the outpatient setting.

In this study, we present a detailed analysis of readmissions of BTT patients with LVAD and aimed to identify the frequency, pattern, etiology, and costs of unplanned readmissions.

Methods

This single-center, retrospective study included 99 unplanned readmissions of a total of 50 consecutive BTT patients (45 males, 5 females; mean age 46.9±10.3 years; range, 19 to 67 years) who were successfully discharged after LVAD implantation between April 2012 and September 2016. Exclusion criteria were as follows: previous LVAD implantation as a destination therapy (DT); having pulsatile-flow ventricular assist device (VAD); in-hospital mortality after LVAD implantation; previous heart transplantation before discharge after LVAD implantation; and having LVAD in an external center and being under follow-up at our hospital. A written informed consent was obtained from each patient. The study protocol was approved by the Istanbul Kartal Koşuyolu Yüksek Ihtisas Training and Research Hospital Ethics Committee. The study was conducted in accordance with the principles of the Declaration of Helsinki.

All decisions for LVAD implantation and candidacy for heart transplantation were made by the Multidisciplinary Heart Transplantation Council. The follow-up examinations including first week after discharge, monthly for six months, then every three months, and after surgery were performed by a certain dedicated team focused on the patients with LVAD. The transplant eligibility of patients with LVAD was reassessed on a regular basis (every six months in stable medical conditions) with detailed echocardiography, cardiac catheterization, and laboratory tests including panel-reactive antibodies. The patients who were applied to suburban hospitals and required follow-up or treatment were transferred immediately to our center within 24 hours. In our routine practice, the outpatient LVAD team always stays in contact with the patients, as well as the manufacturer for any kind of VAD alarms. As the patients with LVADs need special considerations, they are always able to get in touch with emergency on-call VAD coordinator, who also make regular calls to patients. In our study, all LVAD patients requiring hospitalization for any reasons were managed primarily at the reference center. Although anticoagulation goals for LVAD vary between reported studies, we maintained with a target INR of 2.0 to 3.0 and aimed to preserve the INR in the upper limits of target range in HVAD? pump patients with our clinical experience by warfarin according to the guidelines, device type, and recommendations of the manufacturer.[6] Antiplatelet regimens ranged from no treatment to dual therapy during concomitant warfarin treatment. We preferred to administer dual antiplatelet therapy (acetylsalicylic acid 150 mg daily and clopidogrel 75 mg daily) targeting more than one pathway of platelet activation without a high risk of bleeding based on our own experience. Antithrombotic therapies of patients at risk of bleeding, hemolysis or thrombosis were re-arranged individually.

Patient demographic data, hemodynamic measurements before implantation, and readmissions after discharge were evaluated retrospectively. Index hospitalizations were defined as admissions that had a LVAD implantation performed. According to the decision of the heart team, hospitalizations to facilitate elective evaluations after discharge were defined as planned readmissions. Reasons for unplanned readmissions during the study period are shown in Table 1. The remaining hospitalizations due to major problems which were unable to be managed in routine outpatient clinic were accepted as unplanned readmissions. Unplanned readmissions due to any adverse event were classified according to the Interagency Registry for Mechanically Assisted Circulatory Support (INTERMACS) definitions.[7] The overall follow-up information of the patients were collected until the date of June 2017. Longterm outcome measures of the study were as follows: all-cause mortality during LVAD therapy; heart transplantation; and LVAD removal due to myocardial recovery. All in-hospital data of the patients were available in a well-documented hospital electronic records. Survival data were obtained from the national database. We calculated the direct hospital cost for each readmissions based on the insurance reimbursements. All costs were adjusted to the January 2017 consumer price index of Turkey comparing with the relative economic burden of various adverse events.

Table 1: Reasons for unplanned readmissions

Statistical analysis
Statistical analysis was performed using the IBM SPSS version 23.0 software (IBM Corp., Armonk, NY, USA). Categorical variables were presented in number and frequency, while continuous variables were presented in mean ± standard deviation (SD) or median (min-max) values. The Mann-Whitney U test was used to compare continuous variables. Log-rank tests were used to analyze statistical significance in survival differences between the groups. Survival curves were demonstrated with the Kaplan-Meier method. Linear regression method was used to reveal the relationship between annual readmission frequency and follow-up time. A two-tailed p value of <0.05 was considered statistically significant.

Results

All patients included in the study received continuous-flow LVADs as BTT. Overall data of index hospitalizations are shown in Table 2. The median hospital length of stay (LOS) after LVAD implantation was 32 (range, 7 to 200) days. The median follow-up period after discharge was 428 (range, 29 to 1,790) days. Five patients (10%) underwent heart transplantation. Sixteen patients (32%) died during LVAD therapy. Termination rate of LVAD therapy was 2% (n=1) due to myocardial recovery. Cumulative survival of the cohort is shown in Figure 1.

Table 2: Baseline characteristics of patients (n=50)

Figure 1: Cumulative survival of the patients with left ventricular assist device.

A total of 96.2% of the patients were outside the hospital during follow-up. Twelve patients (24%) did not readmit after discharge. Readmission-free survival curve of the patients is shown in Figure 2. The remaining 38 patients (76%) had a total of 112 readmissions. Of these, 99 readmissions (88.4% of all readmissions) were unplanned. The median readmission frequency was 1.7 (range, 0 to 12) per year. Readmission frequency of patients decreased significantly as the follow-up period extended (p=0.002) (Figure 3). The median time to first readmission was 91 (range, 1 to 772) days. Half of the patients were admitted to the hospital within the first 90 days. Survival of patients who were hospitalized within the first 90 days was found to be significantly lower than those without early readmission (log-rank=0.011) (Figure 4). Additionally, in the subsequent follow-up of patients requiring early readmission, the annual frequency of readmission and also cost indices (total admission cost/follow-up period) were significantly higher than the others (p=0.001 and p=0.03, respectively).

Figure 2: Readmission-free survival of the patients with left ventricular assist device.

Figure 3: Relationship between follow-up period and readmission frequency (Scatter/dot plot).

Figure 4: Kaplan-Meier survival curves of patients with and without early (first 90-day) readmissions after discharge.

The most common reasons for unplanned readmissions were major infection (23.2%), neurological dysfunction (22.2%), cardiac causes (12.1%), bleeding (11.1%), and device malfunction (10.1%). However, cardiac causes were characterized with the longest LOS for each admission (Figure 5). When total costs were considered, it was found that readmission due to neurological dysfunction (82,005 USD), device malfunction (73,300 USD) and cardiac reasons (56,449 USD) led to the highest costs, respectively. Etiologies of unplanned readmissions are summarized in Table 3.

Figure 5: Mean length of hospital days according to various etiologies.
SAE: Serious adverse events; CNS: Central nervous system.

Table 3: Analysis of unplanned readmissions according to specific etiologies

Discussion

The efficacy of LVADs for different patient populations is universally confirmed.[1,8,9] Increased clinical experience and extended indications have led to a rapid augmentation in the number of patients with LVAD in recent years.[9] After implantation, in addition to risks of normal population, patients must also cope with LVAD-related complications.[10] Nevertheless, LVAD therapy has been shown to improve the quality of life, compared to medical therapy.[12] As a parameter of quality of life, patients spend an overwhelming majority of their time outside hospital after discharge.[13,14] In our study, patients spent 96.2% of their time at home. The rate of unplanned readmission was 1.7 per year in our cohort, consistent with the previously published data.[4,15,16] In addition, the frequency of readmissions reduced monotonically during follow-up, which indicates that LVAD therapy is associated with further recovery in overall medical profile of patients over time in this population.

Despite many positive effects of LVADs, high readmission rate in which the majority was unplanned according to the previous reports also remained unchanged in our study.[5] Alarge-scale population study form the United States reported a 90-day readmission rate of 53.1%.[17] In our study, the 90-day readmission rate was 50%. Additionally, patients with early readmission showed a poorer prognosis in the long-term in our study. However, there is no consensus on scoring systems about measuring the quality of life and predicting the readmissions in patients with LVAD. Although several risk factors have been identified for different patient groups, the length of initial hospital stay seems to be the most emphasized predictor. We believe that pre-existing comorbidities during index hospitalization and at discharge are associated with early readmissions and also with long-term mortality. Unfortunately, this study is not feasible for the analysis of predictors due to the small sample size and numerous variables.

The main reasons for recurrent readmission in our study group are universal well-defined causes.[14,18] Infection, neurological dysfunction, cardiac causes, device malfunction and bleeding are the most pronounced reasons not only for hospitalizations, but also for prolonged LOS and higher total costs. In several series, major infection was shown as one of the most common causes of readmissions.[5,14,19,20] In our study group, it was also the frequent and repetitive cause for hospitalization. Subgroup analyses revealed that 56% of all readmissions due to infection were device-related. The majority of LVAD-related infections were driveline infections (92%; total 6 patients, 12 readmissions). Readmissions due to driveline infections resulted in longer LOS and also higher costs, compared to other infectionrelated hospitalizations. However, infection-related hospitalizations were often more benign than other adverse events.

Furthermore, neurological deficits were found to be associated with a high mortality risk (40.9%, n=9/22) and caused the highest total cost. Although ischemic brain infarction is rare, it is characterized by prolonged hospitalization. Additionally, the mortality rate was 100% for these patients. The major challenge for patients with neurological dysfunction is the difficult management of delicate balance between bleeding and thrombosis in LVAD.[21] In our daily practice, neurological sequelae also cause a major dilemma in terms of the assessment of transplantation availability, particularly in young patients. In patients with LVAD, we suggest that non-specific symptoms which may be related to neurological disorders need to be more aggressively evaluated than in non-LVAD patients. In our initial experience, all patients were treated with dual antiplatelet therapy and standard anticoagulant therapy (at the upper limit of therapeutic range). However, individualized antithrombotic therapy is definitely reasonable to reduce LVAD-related bleeding (neurological and gastrointestinal).

Another reasons for readmissions are cardiac causes (arrhythmia and right heart failure) characterized by prolonged hospitalization periods. These patients usually wait for an emergency transplant in the hospital due to persistence of cardiac comorbidities. Finally, it should be kept in mind that the majority of readmission studies, as in our study, are based on the first presentation to classify each readmission. However, a substantial proportion of hospitalizations may become complicated over time due to the interaction of different adverse events.

Despite the proportional decrease in costs over time, the increase in the number of patients with LVAD may cause an important financial burden cumulatively.[22] In our study, most of the follow-up costs were related to LVAD-related adverse events. In addition, in terms of total health costs, management of the adverse events with highest cost requires intense effort due to emergency heart transplant necessity (device failure and cardiac causes) or high mortality risk (neurological causes). Akther et al.[18] reported that the most expensive reasons for readmission were device malfunction, cardiac causes, and neurological disorders. In our study, the cost of readmission for neurological reasons was the highest, followed by device malfunction and cardiac causes. In our study group consisting of only BTT patients, we often preferred to refer the patients who were admitted due to a device malfunction to a heart transplant as a first step rather than device exchange. Although adverse events with LVAD are frequent, we believe that it is not feasible to make a cost-effective analysis, due to donor scarcity and lack of medical therapy of comparable to LVAD in efficacy.

Nonetheless, the present study has some limitations. Its retrospective design is the main limitation. In addition, although data of study patients were perfectly recorded and fully available, possible external readmissions and minor complications not requiring hospitalization might have caused a potential bias. Also, our relatively small sample size reflects our initial experience. Therefore, conservative approaches may have resulted in prolonged stays of length and increased costs. The cost analysis was also based on insurance reimbursement, and patient expenditures, employee salaries, and other social care costs were excluded. Finally, this study does not reflect the total economic impact of patients with LVAD, since it only focuses on the proportional financial burdens of etiologies.

In conclusion, unplanned readmission after left ventricular assist device implantation is common, despite the improvement of ventricular assist device technologies and dedicated healthcare. Patients with early readmission have worse survival than those not early readmitted. Major infection, neurological dysfunction, cardiac causes, device malfunction, and bleeding are the most common causes of readmissions. Readmissions due to neurological dysfunction and device malfunction are also associated with high costs. Further studies investigating the causes which induce readmissions may greatly contribute to the long-term survival of patients with a left ventricular assist device and to the improvement of the quality of life of patients.

Declaration of conflicting interests
The authors declared no conflicts of interest with respect to the authorship and/or publication of this article.

Funding
The authors received no financial support for the research and/or authorship of this article.

References

1) Ponikowski P, Voors AA, Anker SD, Bueno H, Cleland JGF, Coats AJS, et al. 2016 ESC Guidelines for the diagnosis and treatment of acute and chronic heart failure: The Task Force for the diagnosis and treatment of acute and chronic heart failure of the European Society of Cardiology (ESC)Developed with the special contribution of the Heart Failure Association (HFA) of the ESC. Eur Heart J 2016;37:2129-200.

2) Arnold SV, Jones PG, Allen LA, Cohen DJ, Fendler TJ, Holtz JE, et al. Frequency of Poor Outcome (Death or Poor Quality of Life) After Left Ventricular Assist Device for Destination Therapy: Results From the INTERMACS Registry. Circ Heart Fail 2016;9. pii: e002800.

3) Yılmaz MB, Akar AR, Ekmekçi A, Nalbantgil S, Sade LE, Eren M, et al. Future of advanced heart failure and mechanical support devices: A Cardiology-Cardiovascular Surgery Consensus Report. Turk Kardiyol Dern Ars 2016;44:175-88.

4) Kimura M, Nawata K, Kinoshita O, Yamauchi H, Hoshino Y, Hatano M, et al. Readmissions after continuous flow left ventricular assist device implantation. J Artif Organs 2017;20:311-7.

5) Smedira NG, Hoercher KJ, Lima B, Mountis MM, Starling RC, Thuita L, et al. Unplanned hospital readmissions after HeartMate II implantation: frequency, risk factors, and impact on resource use and survival. JACC Heart Fail 2013;1:31-9.

6) Feldman D, Pamboukian SV, Teuteberg JJ, Birks E, Lietz K, Moore SA, et al. The 2013 International Society for Heart and Lung Transplantation Guidelines for mechanical circulatory support: executive summary. J Heart Lung Transplant 2013;32:157-87.

7) INTERMACS Adverse Event Definitions: Adult and Pediatric patients. INTERMACS Executive Committee. Available at: https://www.uab.edu/medicine/intermacs/ images/protocol_4.0/protocol_4.0_MoP/Appendix_A_ INTERMACS_AE_Definitions_Final_06122015.docx. [Accesed: March 13, 2019]

8) Yancy CW, Jessup M, Bozkurt B, Butler J, Casey DE Jr, Colvin MM, et al. 2017 ACC/AHA/HFSA Focused Update of the 2013 ACCF/AHA Guideline for the Management of Heart Failure: A Report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Failure Society of America. J Am Coll Cardiol 2017;70:776-803.

9) Ezekowitz JA, O'Meara E, McDonald MA, Abrams H, Chan M, Ducharme A, et al. 2017 Comprehensive Update of the Canadian Cardiovascular Society Guidelines for the Management of Heart Failure. Can J Cardiol 2017;33:1342-433.

10) Prinzing A, Herold U, Berkefeld A, Krane M, Lange R, Voss B. Left ventricular assist devices-current state and perspectives. J Thorac Dis 2016;8:E660-6.

11) Adams EE, Wrightson ML. Quality of life with an LVAD: A misunderstood concept. Heart Lung 2018;47:177-83.

12) Starling RC, Estep JD, Horstmanshof DA, Milano CA, Stehlik J, Shah KB, et al. Risk assessment and comparative effectiveness of left ventricular assist device and medical management in ambulatory heart failure patients: The ROADMAP study 2-year results. JACC Heart Fail 2017;5:518-27.

13) Forest SJ, Bello R, Friedmann P, Casazza D, Nucci C, Shin JJ, et al. Readmissions after ventricular assist device: etiologies, patterns, and days out of hospital. Ann Thorac Surg 2013;95:1276-81.

14) Da Silva M, MacIver J, Rodger M, Jaffer M, Raju S, Billia F, et al. Readmissions following implantation of a continuousflow left ventricular assist device. J Card Surg 2016;31:361-4.

15) Vidula H, Kutyifa V, Johnson BA, Strawderman RL, Harrington D, Polonsky B, et al. Readmission patterns during long-term follow-up after left ventricular assist device implantation. Am J Cardiol 2018;122:1021-7.

16) Slaughter MS, Rogers JG, Milano CA, Russell SD, Conte JV, Feldman D, et al. Advanced heart failure treated with continuous-flow left ventricular assist device. N Engl J Med 2009;361:2241-51.

17) Tripathi B, Arora S, Kumar V, Thakur K, Lahewala S, Patel N, et al. Hospital complications and causes of 90-day readmissions after implantation of left ventricular assist devices. Am J Cardiol 2018;122:420-30.

18) Akhter SA, Badami A, Murray M, Kohmoto T, Lozonschi L, Osaki S, et al. Hospital readmissions after continuous-flow left ventricular assist device implantation: incidence, causes, and cost analysis. Ann Thorac Surg 2015;100:884-9.

19) Agrawal S, Garg L, Shah M, Agarwal M, Patel B, Singh A, et al. Thirty-day readmissions after left ventricular assist device implantation in the united states: insights from the nationwide readmissions database. Circ Heart Fail 2018;11:e004628.

20) Raju S, MacIver J, Foroutan F, Alba C, Billia F, Rao V. Longterm use of left ventricular assist devices: a report on clinical outcomes. Can J Surg 2017;60:236-46.

21) Eckman PM, John R. Bleeding and thrombosis in patients with continuous-flow ventricular assist devices. Circulation 2012;125:3038-47.

22) Lampropulos JF, Kim N, Wang Y, Desai MM, Barreto-Filho JA, Dodson JA, et al. Trends in left ventricular assist device use and outcomes among Medicare beneficiaries, 2004-2011. Open Heart 2014;1:e000109.

Keywords : Bridge-to-transplant, outcome, readmission, transplantation, ventricular assist device
Viewed : 4873
Downloaded : 1122